Risk assessment of deep foundation pits in subway stations based on variable fuzzy sets

doi:10.16265/j.cnki.issn1003-3033.2025.06.1019

Abstract

Abstract:

To accurately identify deep foundation pit collapse risk levels and improve construction safety, a risk assessment model was developed using variable fuzzy set theory. Sixteen influencing factors were screened from four categories: hydrogeology, support conditions, construction operations, and management monitoring. A risk index system was constructed based on these factors with clearly defined grade standards for risk classification. The multiplicative synthesis method was applied to optimally combine subjective weights derived from Stepwise Weight Assessment Ratio Analysis (SWARA) and objective weights calculated via the entropy weight method, forming comprehensive weights that integrate expert judgment and data objectivity. Variable fuzzy set theory was then utilized to process sample data, generating comprehensive grade characteristic values to determine collapse risk levels. Engineering case results show that the evaluation outcomes of method align with actual construction conditions, confirming its scientific validity and effectiveness. Compared to existing approaches, it more accurately reflects risk status by addressing the fuzzy nature of risk boundaries in deep foundation pit projects. This study provides a scientific and practical framework for risk assessment, enhancing safety management in deep foundation pit construction and offering practical value for ensuring project safety and informed risk management decisions.

Key words: subway, deep foundation pit, collapse, variable fuzzy set, risk assessment

CLC Number:

X951交通运输安全

CHEN Zi, QIU Huawan, LIU Jiayu, YANG Siyu, LI Zhiyong. Risk assessment of deep foundation pits in subway stations based on variable fuzzy sets[J]. China Safety Science Journal, 2025, 35(6): 105-110.

Figures/Tables 6

Table 1

Table 2

Table 3

Table 4

Results of collapse risk assessment in deep foundation pit

站点	不同参数组合下等级特征值 $H -$				综合等级特征值H'	风险等级	现场调查结果
站点	α=1, p=1	α=1, p=2	α=2, p=1	α=2, p=2	综合等级特征值H'	风险等级	现场调查结果
A	2.24	2.23	2.26	2.20	2.23	Ⅱ	Ⅱ
B	2.95	2.89	3.11	2.77	2.93	Ⅲ	Ⅲ
C	1.59	1.44	1.56	1.72	1.58	Ⅱ	Ⅱ
D	2.89	3.22	3.08	3.35	3.13	Ⅲ	Ⅲ

Table 4

Fig.1

Table 5

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类别	评估指标	等级
类别	评估指标	Ⅰ低风险)	Ⅱ(中风险)	Ⅲ(高风险)	Ⅳ(极大风险)
水文地质	土的黏聚力X₁/kPa	>40	(30,40]	(15,30]	≤15
	土的内摩擦角X₂/(°)	>24	(19,24]	(14,19]	≤14
	渗透系数X₃/(m·d^-1)	≤0.25	(0.25,2]	(2,10]	>10
	平均地下水位X₄/m	>15	(10,15]	(8,10]	≤8
	降雨量X₅/mm	≤15	(25,15]	(25,50]	>50
支护情况	围护结构厚度X₆/m	>1.2	(1,1.2]	(0.8,1]	≤0.8
	围护插挖比X₇	>2	(1.8,2]	(1.6,1.8]	≤1.6
	内支撑类型与间距X₈	1(混凝土<3.5)	2(混凝土>3.5)	3(钢支撑<3.5)	4(钢支撑>3.5)
施工操作	超挖深度X₉/m	≤0.5	(0.5,1]	(1,2]	>2
	开挖速度X₁₀/(m³·d^-1)	≤2 000	(2 000,3 000]	(3 000,4 000]	>4 000
	开挖方案合理性X₁₁	1(非常合理)	2(合理)	3(基本合理)	4(不合理)
	降排水及时性X₁₂/min	≤60	(60,120]	(120,180]	>180
	开挖深度X₁₃/m	≤8	(8,15]	(15,25]	>25
管理监测	施工规范性X₁₄	1(非常规范)	2(规范)	3(基本规范)	4(不规范)
	监测频率X₁₅/(次·d^-1)	3	2	1	0
	坑周超载比X₁₆	≤1	(1,1.4]	(1.4,2]	>2

站点	X₁	X₂	X₃	X₄	X₅	X₆	X₇	X₈	X₉	X₁₀	X₁₁	X₁₂	X₁₃	X₁₄	X₁₅	X₁₆
A	45	20	1.89	12.6	32	1.13	1.75	2	0.2	3 048	2	105	16.3	3	1	1.1
B	38	18	2.15	12.8	41	1.08	1.72	2	1.2	3 213	3	108	17.2	3	1	1.5
C	48	27	1.65	10.9	34	1.31	1.83	2	0.2	2 890	2	71	14.6	2	2	0.89
D	32	22	2.45	10.3	45	0.98	1.54	2	1.7	3 867	3	105	19.1	3	1	1.3

指标	γ_i	β_i	w_i	指标	γ_i	β_i	w_i
X₁	0.06	0.08	0.07	X₉	0.02	0.01	0.01
X₂	0.05	0.03	0.04	X₁₀	0.03	0.01	0.02
X₃	0.02	0.02	0.02	X₁₁	0.08	0.09	0.09
X₄	0.08	0.06	0.07	X₁₂	0.04	0.06	0.05
X₅	0.06	0.08	0.07	X₁₃	0.02	0.04	0.03
X₆	0.12	0.13	0.13	X₁₄	0.08	0.10	0.09
X₇	0.14	0.08	0.11	X₁₅	0.06	0.03	0.04
X₈	0.04	0.06	0.05	X₁₆	0.10	0.12	0.11

站点	风险评估方法
	未确知测度法^[15]		物元可拓法^[16]		可变模糊集理论
	综合未知测度	评估等级	最大贴近度	评估等级	综合等级特征值H'	评估等级
A	0.91	Ⅱ	0.99	Ⅲ	2.23	Ⅱ
B	0.81	IV	0.91	Ⅲ	2.93	Ⅲ
C	0.89	Ⅱ	0.89	Ⅱ	1.58	Ⅱ
D	0.88	Ⅲ	0.98	Ⅲ	3.13	Ⅲ